植物生态学报 ›› 2025, Vol. 49 ›› Issue (地上地下生态过程关联): 0-0.DOI: 10.17521/cjpe.2024.0243

• •    下一篇

氮添加和降水改变对高寒草甸生态系统地上与地下碳储的影响

张法伟1,李红琴2,祝景斌3,樊博1,周华坤1,李英年1,1,梁乃申4   

  1. 1. 中国科学院西北高原生物研究所
    2. 洛阳师范学院
    3. 枣庄学院旅游与资源环境学院
    4. 日本国立环境研究所
  • 收稿日期:2024-07-25 修回日期:2024-10-11 出版日期:2025-06-20 发布日期:2025-01-15

Response of the above- and below-ground carbon storage to nitrogen addition and precipitation change of alpine meadow ecosystems

  • Received:2024-07-25 Revised:2024-10-11 Online:2025-06-20 Published:2025-01-15

摘要: 高寒草甸生态系统具有重要的碳储功能但相对脆弱,理解其对大气氮沉降和降水格局改变的响应是准确评估全球变化下系统碳收支的科学基础。基于2017年在青藏高原东北隅建立的高寒草甸氮添加(10 g m-2 a-1)和降水改变(减雨50%和增雨50%)试验平台,分析2022–2023年植被生物量和土壤有机碳含量(SOCC)及组分的变化,探讨高寒草甸生态系统碳储对氮水改变的响应。结果表明氮添加和降水改变对群落地上生物量(AGB)无显著交互作用。群落AGB对氮水改变的响应具有显著的功能群依赖性,氮添加处理显著提高莎草类和禾草类AGB。减雨50%处理显著降低群落AGB约27%,但增雨50%处理无显著作用。除了莎草类,其它功能群AGB在群落AGB中的占比无显著变化。0~40 cm地下生物量(BGB)和SOCC对氮水改变的响应微弱,表现出土壤深度和年际的依赖性。氮添加和减雨50%处理分别降低和提高根冠比约31%和83%。氮添加处理仅显著提升表层(0~10 cm)矿物结合态有机碳(MAOC)约31%。氮水改变下的群落AGB的响应比(RR)主要受控于禾草类AGB。0~40 cm BGB的RR受表层和深层(20~40 cm)BGB的影响。0~40cm SOCC的RR由各层SOCC共同驱动。表层BGB直接正向调控表层颗粒态有机碳(POC)并通过POC间接负向影响表层MAOC。群落AGB正向调控深层MAOC但负向影响深层POC。因此,氮水改变的主效应而非交互效应影响了高寒草甸AGB,但对BGB和SOCC的作用微弱。植被生物量对土壤有机碳组分的影响具有深度依赖性。

关键词: 高寒草甸, 生物量, 土壤有机碳, 颗粒态有机碳, 矿物结合态有机碳, 氮添加, 降水改变

Abstract: Aims Alpine grassland ecosystems store vast amounts of organic carbon while are fragile. Understanding the responses of the ecosystem carbon storage to the synchronous atmospheric nitrogen deposition and changing precipitation regimes is critical to project the fate of ecosystem carbon budgets under the context of global change. Methods Based on a manipulation field experiment of nitrogen addition (10 g?m–2?a–1) and precipitation change (precipitation reduction by 50% and increase by 50%) in an alpine meadow on the northeastern Qinghai-Xizang Plateau in 2017, the plant biomass, soil organic carbon content (SOCC) and its fractions were observed from 2022 to 2023, in order to explore the response of ecosystem carbon storage to the changes in nitrogen and precipitation. Important findings The results showed that there were little interaction effects of nitrogen addition and precipitation change. The response of vegetation aboveground biomass to the changes in nitrogen and precipitation was functional group-dependent. Nitrogen addition treatment increased the AGB of graminoid and sedge. Decreased precipitation treatment reduced AGB by 27% while increased precipitation treatment impacted AGB insignificantly. Except for sedge, the proportion of functional group AGB against community AGB changed undetectably. The responses of 0–40 cm belowground biomass (BGB) and SOCC to the changes in nitrogen and precipitation were weak and depth- and year-dependent. The root/shoot ratio reduced by 31% in nitrogen addition treatment and increased by 83% in decreased precipitation treatment, respectively. Nitrogen addition treatment increased surface (0–10 cm) mineral-associated organic carbon by 31%. The response ratio (RR) of vegetation AGB was positively related to graminoid. The RR of 0-40 cm BGB was determined by surface and deep (20-40 cm) BGB positively. The RR of 0-40 cm SOCC was equivalently regulated by each layer SOCC. Surface BGB directly impacted the surface POC positively and indirectly impacted the surface MAOC via POC negatively. The vegetation AGB affected the deep MAOC positively and the deep POC negatively. The main effects, rather than the interaction effects of the changes in nitrogen and precipitation, affect AGB significantly while BGB and SOCC undetectably. The differential effects of plant biomass on soil organic carbon fractions are depth-dependent.

Key words: alpine meadow, plant biomass, soil organic carbon, particulate organic carbon, mineral-associated organic carbon, nitrogen addition, precipitation change

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